Envisioning an Advanced ICT-supported Build-up of Manufacturing
Skills for the Factories of the Future
Joao Costa
1
, Dimitris Kiritsis
1,2
, Poul Kyvsgaard Hansen
3
, Manuel Oliveira
4
, Loukas Rentzos
5
,
Hadrien Szigeti
6
and Marco Taisch
7
1
HighSkillz, Kent, U.K.
2
Ecole Polytechnique Fédérale de Lausanne, Lausanne, Switzerland
3
Allaborg University, Allaborg, Denmark
4
SINTEF, Trondheim Norway
5
University of Patras, Rio Patras, Greece
6
Dassaul Systèmes, Vélizy-Villacoublay Cedex, France
7
Politecnico di Milano, Milano, Italy
Keywords: Manufacturing Skills, ICT for Manufacturing, Factories of the Future.
Abstract: In this paper, we present the main concepts and the aim of the ManuSkills FoF project which is to study the
use of enhanced ICT-based technologies and training methodologies to facilitate an increase of young talent
interest in manufacturing and to support their training of new manufacturing skills. The project will
experiment with a wide range of innovative delivery mechanisms such as serious games and teaching
factory, supported by the use of social media augmented by gamification and leveraging the distribution
channels preferred by young talent. In addition, the project will explore the pedagogical frameworks best
suited to the personalization of individual learning needs taking into account the industrial demand.
ManuSkills will address all three stages of the young talent pipeline (i.e. children, teenagers, young people),
where in the early stages the focus will be to make manufacturing education more attractive to young talent,
whilst in the later stages the focus will be to facilitate transformative deep learning of individuals, with
reduced time-to-competence.
1 INTRODUCTION
When asking young talents, their understanding of
what manufacturing of the future entails could not
be further from the truth. In fact, with the shrinking
of distances to create the global village coupled with
the ever faster pace of advances in technology and
process innovation, one can state clearly that
manufacturing is in a state of constant innovation.
The factory of the industrial revolution, where the
shopfloor was unsafe and dirty, is being replaced by
factories where lean and TQM have dramatically
changed the work environment. A fundamental
switch has taken place, where in the beginning the
workers carried out repetitious tasks, now the focus
is on cognitive interaction with the work
environment through ICT. Consequently, higher
education has become necessary. In addition to
engineering, other competences such as sense
making, dealing with complexity and soft skills, are
also necessary.
Manufacturing goes digital and this is argued to
amount to a third industrial revolution
.
(Economist,
2012). Over the past few decades, manufacturing has
evolved from a more labour-intensive set of
mechanical processes (traditional manufacturing) to
a sophisticated set of information-technology-based
processes (advanced manufacturing). The dirty,
noisy, unsafe workshops have given place to modern
technologies and cleaner work environments.
Everything in the factories of the future will be run
by smarter software. Digitisation in manufacturing
will have a disruptive effect every bit as big as in
other industries that have gone digital, such as office
equipment, telecoms, photography, music,
publishing and films. And the effects will not be
confined to large manufacturers; indeed, they will
need to watch out because much of what is coming
389
Costa J., Kiritsis D., Kyvsgaard Hansen P., Oliveira M., Rentzos L., Szigeti H. and Taisch M..
Envisioning an Advanced ICT-supported Build-up of Manufacturing Skills for the Factories of the Future.
DOI: 10.5220/0004928503890393
In Proceedings of the 6th International Conference on Computer Supported Education (CSEDU-2014), pages 389-393
ISBN: 978-989-758-021-5
Copyright
c
2014 SCITEPRESS (Science and Technology Publications, Lda.)
will empower small and medium-sized firms and
individual entrepreneurs. Launching novel products
will become easier and cheaper. Communities
offering 3D printing and other production services
that are a bit like Facebook are already forming
online—a new phenomenon which might be called
social manufacturing. Things will be made
economically in much smaller numbers, more
flexibly and with a much lower input of labour,
thanks to new materials, completely new processes
such as 3D printing, easy-to-use robots and new
collaborative manufacturing services available
online. The wheel is almost coming full circle,
turning away from mass manufacturing and towards
much more personalised production. According to
the ActionPlanT project vision (ActionPlanT) for
future manufacturing – ‘Manufacturing 2.0’, future
ICT-enabled manufacturing will be:
1. On-demand: To sustain market share and
create employment opportunities,
Manufacturing 2.0 should accommodate
changing demands from a new customer base
and deliver customised products on-demand.
2. Optimal: European enterprises need to be able
to produce products with superior quality, high
security and durability and, at the same time,
competitively priced compared to products
from emerging markets.
3. Innovative: Faster introduction of collective
innovation is one of the three key growth
factors together with human capital and
infrastructures. Innovative thinking, design and
manufacturing will lead the way to
sovereignty, independence and growth of
European manufacturing.
4. Green: Manufacturing is responsible for
significant energy use and consumption of
natural resources. Manufacturing 2.0 needs
focused initiatives to reduce energy footprints
on shop floors and increase awareness of end-
of-life (EoL) product use.
5. Human-centric: Manufacturing 2.0 will
evolve from being perceived as production
centred to human centred with greater
emphasis on generating core value for human
stakeholders. Future plants should be more
accommodating towards the needs of the
European workforce and consider them an
integral stakeholder.
Moreover, since the manufacturing process, in a
broad sense, becomes more and more complex, a big
number of complementary roles will be necessary
within the Factories of the Future, such as:
Virtual enterprise: Supply chain engineers;
Forecasting: Business analyst and data
scientists;
Multi technology product: Industrial
engineers;
Quality: Quality managers;
More complex manufacturing technologies:
Process engineers and planners;
Energy: Energy managers.
In spite of the constant innovation pushing
manufacturing forward, the lack of awareness by
mainstream society implies that young talent does
not choose a career in manufacturing contributing to
a serious shortage of skilled labour. Reaching out to
the young talent is the focus of the ManuSkills
European project, studying the effectiveness of
innovative delivery mechanisms such as serious
games and teaching factory, supported by the use of
social media augmented by gamification.
The paper is organised as follows: in section 2
the main concepts and project objectives are
presented. In section 3 we present the approach we
will follow to develop the concepts, implement them
in an appropriate platform. In section 4 we present
the expected impact to be created by the project
actions, achievements and results.
2 CONCEPTS AND PROJECT
OBJECTIVES
ManuSkills aims to study how best to reach the
young talent using an ICT framework to address all
three stages of the young talent pipeline (i.e.
children, teenagers, young people), where in the
early stages the focus will be to raise awareness
about manufacturing to concerned stakeholders, then
to make manufacturing education more attractive to
young talent, whilst in the later stages the focus will
be to facilitate transformative deep learning of
individuals, with reduced time-to-competence. The
resulting ManuSkills ICT framework is captured in
Figure 1 where the triangle of parents, youth and
teachers access the framework over their preferred
device.
The learning content on the platform is packaged
as learning objects provided by both educational
institutions and industry, which are delivered using a
wide range of mechanisms, such as teaching factory,
serious games, webinar, video player and mobile
apps. ManuSkills will benefit from existing
pedagogical material from within the consortium
and study the effectiveness along with the impact on
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390
Figure 1: ManuSkills ICT Framework.
both raising the awareness and learning amongst
young talent. In fulfilling its aims, ManuSkills will
address the following objectives:
Objective 1: Study the barriers and enablers
towards raising the awareness of manufacturing
and training along the entire young talent
pipeline;
Objective 2: Explore how to successfully
engage young talent with ICT and increase their
interest in manufacturing thus addressing the
talent shortage for Europe to sustain its global
competitiveness;
Objective 3: Study innovative delivery
education mechanisms and training
methodologies to facilitate more effective and
efficient competence development towards the
rapid build-up of existing and emerging
manufacturing skills;
Objective 4: Mobilise stakeholders from
business, government, academia, international
organizations, civil society and
nongovernmental organizations to develop
action plans and influence policy for improving
manufacturing education;
Objective 5: Focus on strengthening
manufacturing education at higher education
levels and STEM related subjects with focus on
engineering in secondary education, addressing
the three target stakeholder groups: children,
parents and educators.
Objective 6: Achieve early impact based on the
ManuSkills proof-of-concept platform and other
project results, and facilitate wider impact
through aggressive dissemination and
networking activities supported by a
sustainable exploitation case.
3 APPROACH
A framework capable of capturing the existing and
future manufacturing skills, could be the basis of a,
currently lacking, reference to professional needs,
related to advanced manufacturing. These skills are
essential to manufacturing companies in order to
improve their innovativeness and competitiveness.
Skilled young talent will strengthen the capacity to
innovate and will give new incentive to industry in
order to hinder the outflow of manufacturing
activities to countries outside Europe. The synthesis
of such a reference framework of manufacturing
skills will be updateable in order to allow for new
skills to be added that may result from new
developments in advanced manufacturing. This
framework will be used as a reference for
manufacturing education and will enable capturing
the main manufacturing skills, required by European
companies for the promotion of innovation and
creativity. The development of this reference
framework will be based on a taxonomy of
manufacturing skills with reference to existing
relevant studies. This taxonomy will identify the
main classes of manufacturing skills needed to
compete in the evolving manufacturing ecosystem. It
will comprise of mainly three categories, namely
processes, equipment and systems. These main
classes include manufacturing skills related to
knowledge and optimization, control and human-
machine interfaces, logistics and information flow,
creativity and innovation.
On the basis of this framework, the project will
define a vision on new approaches for awareness
creation and training for the rapid build-up of
manufacturing skills, using ICT enabling
technologies. This vision will be reflected on a
roadmap that will identify and give insight on the
training technologies and approaches that will attract
the young talent in manufacturing education and
create engineers with manufacturing skills required
by the factories of the future. The roadmap will be
coordinated with both European SME ICT providers
and users, for the development of future
manufacturing skills, related to advanced
manufacturing. This roadmap will have to drive the
knowledge delivery mechanisms and the ICT
technologies needed for assimilating the identified
manufacturing skills, in the context of the future
factories. In addition, the project will undertake an
aggressive social awareness of the roadmap by
European society, resorting to both traditional media
(e.g. broadcast television, internet, press, etc.) and
social media strategies with viral impact (i.e. social
EnvisioninganAdvancedICT-supportedBuild-upofManufacturingSkillsfortheFactoriesoftheFuture
391
networks, gamified apps, etc.). Existing ICT tools
that can contribute to the rapid build-up of
manufacturing skills will have to be enhanced and
extended, while the need for new tools will be
identified. The aim will be to boost competitiveness
and innovation in European manufacturing that
would be requiring a workforce with advanced
manufacturing skills.
3.1 Additional Steps
Some of the required steps to bring about desired
impact have been already mentioned in the previous
paragraphs. Additional steps that ManuSkills will
take are summarized as follows:
ManuSkills project will involve relevant
stakeholders as part of the development and
deployment process, i.e. there will be meetings,
seminars and other events with representatives
from educational and research authorities and
associations as well as for the relevant interest
groups (e.g. primary/secondary school teachers,
parents representatives, researchers, university
professors) within the STEM education.
Building on existing professional networks of
teachers and teacher associations will provide
opportunities to disseminate ManuSkills results
and furthermore foster cooperation between
schools, collaborative reflection, exchange of
ideas and experiences and quality development.
There will be constant communication of results
and participation in discussions through relevant
channels (such as newspaper, television,
journals, conferences, web blogs etc.) through
the whole duration of the project. The main
results emerging from ManuSkills project are
very likely to get a wide audience and a direct
impact on debates in national and international
contexts.
Most of the project partners have already
established networks with high schools,
universities and industry in their countries and
have been purposely chosen to participate and
contribute to ManuSkills in order to build the
community of stakeholders and reach the
desired impact through established channels.
The stakeholders within established networks
all recognize the importance of STEM in a
knowledge based society and the urgent need to
enhance young people’s interest towards STEM.
3.2 European Added Value
ManuSkills needs to take into the consideration the
large European context as the TEL solutions to be
implemented in schools, which are applicable within
one context (i.e. within one country), could not
simply be transferrable to other contexts (i.e. other
countries). ManuSkills project is also following the
initiative “Science Education NOW” (EU, 2007)
which recommends that the articulation between
isolated national activities in STEM education and
those funded at the European level must be
improved.
Several barriers can emerge in the deployment
process of the ManuSkills ICT Framework (such as
infrastructural barriers, accessibility barriers,
legislative and education policy obstacles, lack of
means to ensure long-term sustainability etc.) and in
the European context; all these barriers strongly
differ from country to country. ManuSkills will do
the analysis of the present state of the different
educational systems and corresponding institutional
practices in the partners’ countries to identify
country specific drivers and barriers (e.g. related to
curriculum and pedagogy, infrastructure, capacity-
building, language and content, financing etc.) to
ensure the wide implementation of the ManuSkills
results in different European contexts.
4 EXPECTED IMPACT
The expected higher level impacts of the ManuSkills
project are the following:
Penetrate new application areas (e.g. high
customisation, end-of-life product engineering
and manufacturing), close to the market and
opening new markets;
Strengthen supply-side SMEs by enabling them
to supply manufacturers with new equipment
and components for improved manufacturing
operations;
Leveraging innovation capacity and
competitiveness of European producers of laser
manufacturing equipment and their suppliers, in
particular SMEs, and of the users of such
equipment;
ManuSkills will contribute only indirectly to the
above impacts through the preparation of new
generations to become eager for developing skills in
advanced manufacturing and contribute in the
increased competitiveness of European
manufacturing industry.
We think that the main strategic impact
generated by ManuSkills will be addressing the
shortage of talented skills in manufacturing. The
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World Economic Forum report “The Future of
Manufacturing. Opportunities to drive economic
growth” (WEF, 2012) is stated:
“An estimated 10 million jobs globally with
manufacturing organizations cannot be filled today
due to a growing skills gap. Despite the high
unemployment rate in many developed economies,
companies are struggling to fill manufacturing jobs
with the right talent. Emerging nations cannot fuel
their growth without more talent. Access to talent
will become more important and more competitive.
The skills gap that exists today will not close in the
near future, which means companies and countries
that can attract, develop and retain the highest
skilled talent – from scientists, researchers and
engineers to technicians and skilled production
workers – will come out on top. In the race to future
prosperity, nothing will matter more than talent.”
We believe that ManuSkills main impact will be
to contribute in reducing this gap, by increasing in
the young talented people the awareness of a
potential interesting professional career in the
manufacturing sectors.
Anyhow more detailed direct impacts created by
ManuSkills will be generated by the produced
results in medium-long term and short, term as
follows. Being medium-long term the quantification
of the impact is vepry difficult to be done.
To increase the competitiveness of the European
companies by providing them the talented
skilled workers;
Innovation is more and more dependent on
talented scientists and technicians. ManuSkills
will help have an impact on the Europe 2020
Flagship Initiative on Innovation Union;
To raise the awareness of publishers and
learning content providers towards the growing
demand of adapted manufacturing education
taking into accounts the rapid evolution of
technology and the inspirations of the young
people. This will increase the quantity and the
quality of the education content available in
internet and easy to be reached;
Systematic approach for continuous
reinforcement of manufacturing by emerging
technologies through developing strategies for
providing appropriate training to acquire the
related skills;
Putting the humans at the centre of interest in
manufacturing to remain competitive and
innovative through institutionalisation of
continuous and lifelong learning of the
employees to improve their skills and increase
their capabilities.
5 CONCLUSIONS
This envisaged evolution brings new needs for skills
development. The adaptation of the educational
content and its delivery mechanisms to the new
requirements of knowledge-based manufacturing,
the provision of integrated engineering
competencies, including a variety of soft skills, the
promotion of the innovation and entrepreneurship
spirits, as well as an interdisciplinary thinking,
reflecting the increasing integration of different
areas of knowledge in manufacturing, are considered
as major priorities.
The ActionPlanT project has delivered a
validated set of recommendations and guidelines for
an effective development of ICT for manufacturing
skills. On top of that, the ManuSkills project will
deliver an ICT framework and a roadmap for
manufacturing awareness and skills development
ACKNOWLEDGEMENTS
The research leading to these results has received
funding from the European Community's Seventh
Framework Programme (FP7/2007-2013) under
grant agreement n° 609147.
The work in the ManuSkills project is a common
effort among all its contributing partners: Aalborg
University, EPFL, Dassault Systèmes, HighSkillz,
POLIMI, SINTEF and University of Patras.
REFERENCES
ActionPlanT (2011), ICT FOR MANUFACTURING: The
ActionPlanT Vision for Manufacturing 2.0.
Economist (2012), A third industrial revolution, Special
report: Manufacturing and innovation, April 2012,
http://www.economist.com/node/21552901.
EU (2007). Science Education NOW! – Renewed
Pedagogy for the Future of Europe. Brussels:
European Commission, High Level Group on Science
Education.
WEF (2012), The Future of Manufacturing. Opportunities
to drive economic growth, World Economic Forum.
April 2012.
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